Update and Review on the Surgical Management of ... - CiteSeerX

Download PDF
4 downloads 45 Views 257KB Size Report
Comment
Jun 10, 2014 - (2) Experimental use of Mohs surgery for in situ melanoma; and (3) Surgical ... Current guidelines for the surgical management of a primary ...
Healthcare 2014, 2, 234-249; doi:10.3390/healthcare2020234 OPEN ACCESS

healthcare

ISSN 2227-9032 www.mdpi.com/journal/healthcare Review

Update and Review on the Surgical Management of Primary Cutaneous Melanoma Solmaz Niknam Leilabadi 1, Amie Chen 1,†, Stacy Tsai 1,†, Vinaya Soundararajan 1, Howard Silberman 2 and Alex K. Wong 1,* 1

2



Division of Plastic and Reconstructive Surgery, Keck School of Medicine, University of Southern California, 1510 San Pablo St., Suite 415, Los Angeles, CA 90015, USA; E-Mails: [email protected] (S.N.L.); [email protected] (A.C.); [email protected] (S.T.); [email protected] (V.S.) Department of Surgery, Keck School of Medicine, University of Southern California, 1510 San Pablo St., Suite 412, Los Angeles, CA 90015, USA; E-Mail: [email protected] These authors contributed equally to this work.

* Author to whom correspondence should be addressed; E-Mail: [email protected]; Tel.: +1-323-442-7920; Fax: +1-323-442-7573. Received: 19 November 2013; in revised form: 17 April 2014 / Accepted: 6 May 2014 / Published: 10 June 2014

Abstract: The surgical management of malignant melanoma historically called for wide excision of skin and subcutaneous tissue for any given lesion, but has evolved to be rationally-based on pathological staging. Breslow and Clark independently described level and thickness as determinant in prognosis and margin of excision. The American Joint Committee of Cancer (AJCC) in 1988 combined features from each of these histologic classifications, generating a new system, which is continuously updated and improved. The National Comprehensive Cancer Network (NCCN) has also combined several large randomized prospective trials to generate current guidelines for melanoma excision as well. In this article, we reviewed: (1) Breslow and Clark classifications, AJCC and NCCN guidelines, the World Health Organization’s 1988 study, and the Intergroup Melanoma Surgical Trial; (2) Experimental use of Mohs surgery for in situ melanoma; and (3) Surgical margins and utility and indications for sentinel lymph node biopsy (SLNB) and lymphadenectomy. Current guidelines for the surgical management of a primary melanoma of the skin is based on Breslow microstaging and call for cutaneous margins of resection of 0.5 cm for MIS, 1.0 cm for melanomas ≤1.0 mm thick, 1–2 cm for melanoma thickness of 1.01–2 mm, 2 cm

Healthcare 2014, 2

235

margins for melanoma thickness of 2.01–4 mm, and 2 cm margins for melanomas >4 mm thick. Although the role of SLNB, CLND, and TLND continue to be studied, current recommendations include SLNB for Stage IB (includes T1b lesions ≤1.0 with the adverse features of ulceration or ≥1 mitoses/mm2) and Stage II melanomas. CLND is recommended when sentinel nodes contain metastatic deposits. Keywords: primary cutaneous melanoma; melanoma; surgical management of melanoma; surgical margins of melanoma; sentinel lymph node biopsy in melanoma; lymphadenectomy in melanoma

1. Introduction Melanoma accounts for 75% of all deaths related to skin cancer. It is a neoplasm in which there is the malignant transformation of melanocytes, the cells that are capable of forming the pigment melanin. Melanocytes arise most commonly in the skin of any part of the body, but may rarely occur in the eye and mucous membranes of various organs. The goal of this review is to discuss the surgical management of cutaneous melanoma. 2. Brief History, Staging Overview, and Current Guidelines Melanoma was first clinically described in 1820 by English general practitioner William Norris, who presented the first genetic, clinical, and epidemiologic features of the disease and also proposed treatment options, including the need for wide excision of skin and subcutaneous tissue to minimize recurrence [1]. In 1907, British physician W. Samson Handley [2] published an analysis of satellite metastases in which he advocated surgical margins of 2.54 cm, leading to guidelines in the 1970s and 1980s of 5 cm cutaneous excision margins independent of tumor thickness [3]. In 1969 and 1970, physicians Wallace H. Clark, Jr. and Alexander Breslow independently described tumor invasiveness and thickness relative to prognosis. Melanoma microstaging (T-stage) using the Clark Classification (Table 1) was based on the anatomic level of local invasion (Figure 1), whereas the Breslow Classification was based on the vertical thickness of the invasion in millimeters. In accordance with the recommendations of the American Joint Commission on Cancer (AJCC) [4], T microstaging now is determined exclusively by the Breslow classification. In the past several decades, surgical resection of the primary lesion and a margin of the surrounding normal skin based on the Breslow classification has been well studied and has led to increasingly conservative margins [5]. The National Comprehensive Cancer Network (NCCN) combined several large randomized prospective trials, such as the Intergroup Melanoma Surgical Trial [6] and the World Health Organization’s 1988 study [7], along with consensus from experience to propose current guidelines for melanoma excision. These guidelines recommend 0.5 cm cutaneous margins of resection for melanoma in situ (MIS), though the NCCN notes that >0.5 cm margins may be needed for lentigo melanoma (LM), 1.0 cm cutaneous margins for thin lesions defined as ≤1.0 mm thick, 1.0–2.0 cm for intermediate-thickness lesions defined as 1.01–2 mm thick, 2.0 cm for intermediate-thickness lesions defined as 2.01–4 mm thick, and 2.0 cm for thick lesions defined as

Healthcare 2014, 2

236

>4 mm (Table 2) [8]. These recommendations are occasionally modified in the resection of lesions where there are aesthetic and functional concerns, for example, melanomas of the eyelid or cheek. Table 1. Clark classification for melanoma, level of invasion. Level I Level II Level III Level IV Level V

Involving only the epidermis, in situ Invasion of papillary dermis, does NOT reach papillary-reticular dermal interface Invasion through papillary dermis, does NOT penetrate reticular dermis Invasion into reticular dermis Invasion into subcutaneous tissue

Figure 1. Layers of tissue and Clark level invasion.

Table 2. The National Comprehensive Cancer Network recommendations for surgical margins in melanoma excision. Tumor microstage Melanoma in situ (Tis) Thin (T1) Intermediate (T2) Intermediate (T3) Thick (T4)

Thickness ≤1.0 mm 1.01–2 mm 2.01–4 mm >4 mm

Margin 0.5 cm 1.0 cm 1.0–2.0 cm 2.0 cm 2.0 cm

Under AJCC guidelines, the anatomic and prognostic staging group (Stages 0–III) is based on three characteristics: the tumor (T) microstage (Breslow level), the lymph node (N) classification (the pathologic status of the lymph nodes within the primary nodal basin associated with the anatomic location of the melanoma), and the metastasis (M) classification (the absence or presence, including the anatomic location, of distant metastatic disease) (Tables 3–6). In general, the Breslow thickness correlates with prognosis: the thicker a tumor the greater chance that the melanoma will have spread. Within each T grouping, the prognosis is impaired by the finding of ulceration or one or more mitoses per square millimeter (Tables 3–6). While thickness, ulceration, and mitoses have been used to define TNM categories and stage groupings, mitotic rate has now been identified as an independent predictor of survival. A multifactorial analysis of 10,233 patients identified it as the second most significant predictor of survival after thickness [9]. Thus, mitotic rate has been added as a required element in staging of melanoma [9].

Healthcare 2014, 2

237

Table 3. American Joint Committee on Cancer Tumor (T) Classification. TX T0 Tis T1a T1b T2a T2b T3a T3b T4a T4b

Tumor cannot be assessed No evidence of tumor Tumor remains on epidermis Tumor ≤1.0 mm thick, without ulceration and mitosis 4.0 mm, without ulceration Tumor >4.0 mm, with ulceration

Table 4. American Joint Committee on Cancer Regional Lymph Node (N) Classification. NX N0 N1a N1b N2a N2b N2c N3

Lymph nodes cannot be assessed No spread to lymph nodes Microscopic spread to 1 lymph node Macroscopic spread to 1 lymph node Microscopic spread to 2–3 lymph nodes Macroscopic spread to 2–3 lymph nodes In transit met(s)/satellite(s) without metastatic nodes 4 or more metastatic nodes, or matted nodes, or in transit met(s)/satellite(s) with metastatic node(s)

Table 5. American Joint Committee on Cancer Distant Metastasis (M) Classification. M0 M1a M1b M1c

No metastasis Metastasis to distant skin, subcutaneous tissue, or distant lymph nodes Metastasis to lungs Metastasis to all other visceral sites, or any distant metastasis combined with elevated blood LDH level

Table 6. America Joint Committee on Cancer Anatomic Staging/Prognostic Groups. Stage 0 Stage IA Stage IB Stage IIA Stage IIB Stage IIC Stage IIIA Stage IIIB

Stage IIIC Stage IV

Tis, N0, M0 T1a, N0, M0 T1b or T2a, N0, M0 T2b or T3a, N0, M0 T3b or T4a, N0, M0 T4b, N0, M0 T1-T4a, N1a or N2a, M0 T1-T4b, N1a or N2a, M0 T1-T4a, N1b or N2b, M0 T1-T4a, N2c, M0 T1-T4b, N1b or N2b, M0 T1-T4b, N2c, M0 Any T, N3, M0 Any T, any N, any M

Healthcare 2014, 2

238

3. Surgical Diagnosis of Melanoma: Types of Biopsy Pigmented lesions that are larger than several millimeters in diameter, are enlarging, variegated in pigmentation, and have irregular borders, or are ulcerated and/or bleeding raise the clinical suspicion of melanoma, and thus biopsy is indicated. The purpose of the biopsy is to establish the diagnosis of melanoma and, if positive, provide sufficient material to determine the indication for sentinel node analysis (discussed below) and establish the extent of the cutaneous margins that should be obtained at the time of definitive surgical excision. Although various biopsy techniques are described, including incisional, excisional, shave and punch biopsies, excisional biopsy is the technique that is highly recommended by the authors and both the NCCN and AJCC. It is the only technique that clearly establishes the diagnosis and definitive T classification [4,8,9]. Excisional biopsy eliminates the potential sampling errors of the partial excisions obtained with punch biopsy and incisional biopsy. The recommendations for an excisional biopsy are 1–3 mm and 1–2 mm margins from the NCCN [8] and the AJCC, respectively [4,9]. Partial incisional or punch biopsies are acceptable for larger lesions and should be taken from the most suspicious areas of the lesion. Shave biopsies are frequently problematical for surgical planning since they often transect the deep portion of the tumor, in which case the T classification is not definitively determined. Hence, the AJCC recommends against shave biopsies [4,9]. Although excisional biopsies are recommended, there are circumstances in which they may not be appropriate, including lesions with low suspicion for melanoma, large lesions with a diameter >2 cm, large facial or acral lesions, or where excision may be associated with aesthetic concerns [10,11]. 4. Surgical Margins for Melanoma in-Situ (MIS) While recent studies confirmed NCCN guidelines for thick and intermediate-thickness melanomas, data supporting optimal margins for MIS have not been as conclusive. Current NCCN guidelines (Version 2.2014) for MIS call for a 0.5 cm cutaneous margin of resection [12]. Greater margins may be required for large in situ lentigo maligna lesions. In recent years there has been considerable interest in applying Mohs micrographic surgery (MMS), useful in non-melanoma skin cancers [13], to the management of melanoma in situ in order to limit removal of non-diseased tissue in cosmetically sensitive areas [14]. MMS is a tissue-sparing surgery that allows for histological clearance with minimal amount of tissue excision. MMS for the treatment of melanoma has been controversial and experimental since the success of MMS depends on a contiguous tumor growth pattern, while melanoma is known to have satellite metastases [15]. However, there is mounting evidence that MMS for the treatment of melanoma could lead to equivalent or lower local recurrences and better survival rates compared to conventional surgery. One of the first studies to explore MMS versus wide margin excision in melanoma was done by Zitelli et al. in 1997 [16]. In this study, 535 consecutive patients with melanomas that varied in location and thickness underwent MMS and were followed for 5 years. The study revealed that when comparing each thickness group, 5-year survival and metastasis rates were equal or better in the MMS treated patients than the 15,798 historical control patients who underwent wide margin excision. Other such studies by Zitelli and colleagues that included more than 1000 cases over 15 and 22-year-periods have been extensively reviewed in several studies, including

Healthcare 2014, 2

239

recent review papers by Whalen et al. [13] and Hui et al. [15] The Zitelli studies found a local recurrence rate of 0.5% for MIS when treated with MMS compared to 6% for MIS treated with standard surgery [17]. With increased utilization of MMS to accurately assess peripheral clearance, the adequacy of the standard 5 mm margins for melanoma in situ has been debated. In a large study by Kunishige et al. [18] of 1120 cases of MIS treated with MMS, the effectiveness of 9 mm compared to 6 mm surgical margins was confirmed with excision success rates of 86% for 6 mm margins and up to 98.9% for 9 mm margins; margin widths less than 6 mm were not studied. In addition, subtypes of MIS were not specified so it is not known whether the relatively larger margins could be due to a high percentage of cases with lentigo melanoma (LM), a subtype of MIS that is a more aggressive, invasive, and irregularly-shaped type of MIS in chronically sun-exposed areas. Despite the limitations, the study suggested that MIS could be treated as early invasive melanoma with surgical margins at least 9 mm. Erickson et al. [19] further discussed surgical margins for MIS, especially in regard to LM, by reviewing 15 studies from 1997 to 2008 that used MMS to assess clearance and minimize surgical margins. They found a reported recurrence rate of 6%–20% of LM associated with surgical margins of 5 mm, and thus concluded that margins larger than 5 mm may be required for the clinically ill-defined LM lesions. Although these studies call into question the adequacy of surgical margin of 0.5 cm for MIS, the NCCN recommendations continues to be 0.5 cm [8]. 5. Surgical Margins for Thin Melanomas The NCCN and AJCC recommendations for thin melanomas defined as ≤1.0 mm is excision with margins of 1.0 cm [4,8]. Although the latest AJCC guidelines now requires mitotic rate as an element to define the staging of the melanoma, the surgical margin of 1.0 cm remains for thin melanomas. 6. Surgical Margins for Intermediate-Thickness Melanomas Data for melanomas of intermediate thicknesses have been well investigated in multiple large randomized trials. These trials include the WHO 1988 study [7] of 612 patients that compared 1 cm vs. 3 cm surgical margins for melanoma less than 2 mm-thick, the Intergroup trial [6] in 2000 that compared 2 cm vs. 4 cm surgical margins for 740 patients with 1–4 mm-thick melanomas, and the Thomas et al. [20] trial in 2004 of 900 patients that compared 1 cm vs. 3 cm margins for melanomas thicker than 2 mm. Results from the WHO and Intergroup study suggested that intermediate-thickness melanomas could be treated by 1–2 cm excision margins. The Thomas trial found that 1 cm margins were associated with higher local recurrence for melanomas thicker than 2 mm compared to 3 cm margins, though with similar overall survival rates [6,7,20]. These findings generated the NCCN guidelines for intermediate-thickness melanomas and further divided them into the two categories of 1.01–2 mm and 2.01–4 mm with recommended clinical margins of 1.0–2.0 cm and 2.0 cm, respectively [8]. In a multicenter randomized trial, Gillgren et al. studied 936 patients from 1992 to 2004 with melanomas thicker than 2 mm and compared 2 cm vs. 4 cm surgical excision margins and found no difference in the 5-year overall survival (65%) between the two groups [21]. When patients were stratified into groups based on Breslow classification of tumor thickness, the Gillgren trial confirmed the safety of 2 cm margins for melanoma in the intermediate-thickness category (2.01–4 mm).

Healthcare 2014, 2

240

7. Surgical Margins for Thick Melanomas Relative to the abundance of data for the intermediate-thickness melanomas, there is a paucity of data for thick melanomas. For thick melanomas (>4 mm), it is unclear whether margins exceeding 2 cm affect local recurrence and survival rates owing to the fact that thick melanomas may reflect biologic aggressiveness of the melanoma that cannot be cured through wide excision alone [5]. A 1998 study by Heaton et al. found that excisional margins wider than 2 cm had no significant benefits to local control or disease free survival [22]. However, a recent prospective study in 2013 of 637 patients conducted at the Melanoma Institute Australia found that patients that underwent 2 cm or less surgical margins for thick melanomas (>4 mm) were found to have twice the risk of local recurrence compared with those who had >2 cm surgical margins [23]. The studies by Thomas et al. [20] and Gillgren et al. [21] described above in the intermediate-thickness melanomas section were limited to melanomas thicker than 2 mm; however, they did not differentiate between 2.01–4 mm intermediate and >4 mm thick melanomas. The current standard according to NCCN and AJCC is excision margins of 2 cm for thick (>4 mm) melanomas [4,8]. 8. Management of Regional Lymph Nodes: Sentinel Lymph Node Biopsy and Lymphadenectomy 8.1. Introduction An important prognostic indicator for melanoma is the disease status of regional lymph nodes inasmuch as the initial melanoma metastasis is likely to occur through the lymphatic system. The first one or several regional lymph nodes to receive metastatic deposits are designated the “sentinel lymph nodes”. The pathology of melanoma suggests that sentinel lymph node (SLN) involvement may then be followed by spread of the cancer to more distal regional nodes [24]. In the absence of clinically detectable nodes, SLN biopsy (SLNB) has now been adopted as the standard of care, depending on the T-stage (see below). To locate the SLNs (which are clinically occult) at surgery, two tracers are available. Lymphoscintigraphy using a radioisotope, Tc-99, injected around the tumor within 24 hours of surgery, results in radioactivity in the SLNs, which is detected intraoperatively with a gamma probe. The second tracer is a vital dye (usually lymphazurin blue or methylene blue) that is injected intradermally at the periphery of the lesion at the time of surgery. The vital dye travels to the SLNs and stains them blue. Surgeons may use one or both markers to determine the nodes to be removed. The use of both markers is associated with a slightly higher identification rate of the SLNs. If the SLNs are free of metastatic disease it is highly unlikely that the remaining regional nodes bear metastases (see below). SLN biopsy has prognostic value and can determine the stage of melanoma without subjecting a patient to the heretofore recommended elective lymph node dissection (ELND) [25]. When compared to a standard complete lymphadenectomy, a SLNB is less invasive and has minimal complication risks [24]. If the SLNB is positive for metastases by light microscopy or immunohistochemistry, a completion lymph node dissection (CLND), where the rest of the lymph nodes are explored and examined, is currently recommended [12,26–28]. Prior to CLND systemic staging by CT or CT-Pet scan should be considered [12]. CLND serves two purposes: the first is to more accurately assess the stage and prognosis of the melanoma and the second is to prevent relapse in the nodal basin. As noted above, if a SLNB is negative for metastatic disease, it is most likely that the

Healthcare 2014, 2

241

other non-sentinel nodes in the basin are negative for cancer cells as well [29]. However, distant disease can occasionally occur without nodal metastases, but positive regional nodes are more likely the major markers for distant disease [25]. Patients with clinically detectable lymph nodes proven by preoperative biopsy to be positive for metastases, undergo a therapeutic lymph node dissection (TLND) and forego a SLNB [30]. CLND when the SLNB is positive is currently the recommended standard care for melanoma in accordance with guidelines jointly promulgated by the Society of Surgical Oncology and the American Society of Clinical Oncology [26,27]. 8.2. Utility of Sentinel Lymph Node Biopsy Thin melanomas less than 1.0 mm of Breslow thickness have a very low rate of positive SLN, 1.0 mm. A false-negative result from a SLNB ranges from 1.5% to 4.1%, except in the case of head and neck melanomas where the false-negative rate ranges from 3.3% to as high as 44% [40–44]. However, it is widely accepted as an important staging tool for melanomas and a strong independent predictor of outcomes in melanomas 1.2–3.5 mm in thickness [45]. Histopathological thickness of the melanoma (i.e., Breslow microstaging) has been the most reliable predictor of SLN status. Tumors of intermediate thickness have been found to benefit most from the SLNB staging. SLNB for intermediate thickness melanomas is most useful in identifying patients who have early micro-metastases and who then have an indication under current guidelines for regional lymphadenectomy as well as adjuvant therapy [31,32,46]. Even so, there is some variability as to what is considered an intermediate thickness tumor based on Breslow thickness. Landi et al. [31] studied 455 melanoma patients and found that intermediate thickness melanomas of 0.76 to 4.0 mm obtain the most prognostic value from SLNB. Lens et al. [46] reviewed 12 studies through 2001 for a total of 4218 patients and concluded that Breslow thickness correlates with the presence of sentinel node metastasis. Incidence of positive SLNB increased as thickness of the melanoma increased. Melanomas between 1.51 and 4.0 mm were found to have a significantly higher risk of a positive SLNB compared to melanomas between 1.0 and 1.5 mm thickness. Therefore, SLNB serves as an effective and appropriate staging procedure for melanomas between 1.51 and 4.0 mm. Mays et al. [32] noted that although melanomas between 1.0 to

Healthcare 2014, 2

242

2.0 mm thick are likely to have a negative SLNB, patients with these melanomas exhibit diversity in the biologic behavior of their tumor; however, it has been difficult to indicate another prognostic factor to identify a subset of these patients who would benefit from SLNB. Therefore, SLNB is recommended for all patients with a tumor between 1.01 to 2.0 mm [4,32]. SLNB for thick melanomas >4 mm in Breslow thickness has been questioned due to the poor prognosis and to the high risk of hematogenous dissemination in this subset of patients [47–49]. Oliveira Filho et al. [48] found that regardless of the histopathological SLN status of thick melanomas, patients had similar rates of recurrence and mortality. According to such findings, SLNB may not be indicated for patients with thick melanomas [48]. In contrast, SLN status has been found to be the most important prognostic factor for survival and may serve as a useful tool to stratify patients in this high-risk group into adjuvant trials [31,50]. Furthermore, some physicians have found that a negative SLN status may identify a subset of patients with a more favorable prognosis and who may be long-term survivors [46,47]. For example, Cherpelis et al. [47] found that SLN status was predictive of disease-free survival for patients with thick melanomas. Consensus is that SLNB is currently indicated in all thick melanomas with no evidence of systemic metastasis on CT or PET imaging. In summary, current AJCC guidelines call for SLNB for patients with T1b or T2 tumors (i.e., clinical stages IB and II) [4]. 8.3. Utility of Completion Lymph Node Dissection Following a positive SLN result, patients are offered CLND as part of the standard care protocol as discussed above. Of concern, however, is that a CLND may result in surgical morbidity. Previous reports have noted that only 14% to 28% of patients with positive SLNs harbor disease in other regional lymph nodes [51–53]. Similar evidence of a low incidence of non-sentinel node involvement was observed in the First Multicenter Selective Lymphadenectomy Trial (MSLT I) [28]. These data indicate that CLND would be an unnecessary procedure for that large subset of patients with positive SLNs but no non-sentinel node involvement. Thus, CLND would be of potential benefit if the patients likely to harbor metastatic disease in non-SLN could be identified [54]. In various analyses, an array of features appear to correlate with non-sentinel node involvement, including ulceration, satellitosis, neurotropism, multiple positive SLNs, a SLN with multifocal involvement or tumor deposits >2 mm, extranodal extension, capsular involvement, and primary tumor thickness >2 mm [55]. However, the absence of these features is not sufficiently predictive of disease-free non-sentinel nodes to alter the current standard of care when the SLN is positive. Whether or not CLND provides a survival advantage for patients who have undergone the procedure remains a topic of debate. Previous studies have demonstrated a survival advantage for melanoma patients who underwent CLND compared to melanoma patients who underwent therapeutic lymph node dissection (TLND) after developing clinically palpable disease. A German multicenter retrospective study found a 12% survival benefit at 5 years for patients who had a positive SLNB result followed by CLND compared to patients who underwent a later TLND [56]. A study by Morton et al. found a 5 year survival advantage of 22% for patients who underwent immediate lymphadenectomy after positive SLN biopsy results as opposed to delayed lymph node dissection (DLND) for nodal disease that developed during a period of clinical observation [57]. Pasquali et al. [58] conducted a

Healthcare 2014, 2

243

retrospective series and reported a difference of 18% in the 5 year overall survival rate between patients in the CLND group compared to patients in the TLND group. The percentage of survival benefit reported was similar to the value reported in other studies, however it lacked statistical significance. In contrast, Rutkowski et al. conducted a retrospective analysis and found no significant difference in overall survival and disease-free survival between the group of patients that underwent CLND after a positive SLNB result versus the group of patients who underwent TLND due to clinical lymph node metastasis [59]. Recently, in February 2014, the New England Journal of Medicine published the Final Trial Report of Sentinel-Node Biopsy versus Nodal Observation in Melanoma which compared 2 groups: (1) underwent wide excision and SLN biopsy with CLND if the SLN was positive for disease; and (2) underwent wide excision alone with observation alone and a TLND if a node becomes clinically evident. This study found that the 10-year disease free survival for group 1 versus group 2 in melanomas of intermediate thickness 1.20–3.50 mm was 71.3% vs. 64.7% (p = 0.01) respectively and in thick melanomas >3.50 mm, 50.7% vs. 40.5% (p = 0.03) respectively [60]. Furthermore, the 10-year melanoma specific survival for melanomas ≥1.20 mm was 62.1% vs. 41.5% in the two groups respectively [60]. This shows that a CLND improves disease free and melanoma free survival when a SLN biopsy is positive compared to observation alone. Pilko et al. [61] compared the overall survival of patients with a melanoma of Clark level III and a Breslow thickness of 1.00 mm or more or melanomas of Clark level IV or V and any Breslow thickness. Patients were sorted into three groups: (1) patients with a positive SLNB who then underwent CLND; (2) patients initially clinically node negative who presented with clinically positive nodes during observation who then underwent DLND; and (3) patients who had synchronous primary melanoma and regional lymph node metastases. Patients with synchronous primary melanoma and regional lymph node metastases had the poorest 5 year overall survival. Patients who had a CLND for a SLN metastasis with a tumor diameter 5.0 mm had similar survival as patients with synchronous primary melanoma and regional lymph node metastasis [61]. These results emphasize the prognostic heterogeneity among stage III melanoma patients, particularly among patients with positive SLNs. 8.4. Arguments against Sentinel Lymph Node Biopsy and Completion Lymph Node Dissection SLNB and CLND are invasive procedures that may be associated with various postoperative complications. The MSLT I trial reported an acute complication rate of 10% in patients who had SLNB alone and 37% in patients who had CLND [62]. The Sunbelt Melanoma Trial saw a 4.6% total complication rate among patients who underwent SLNB alone and a 23.2% rate in patients who had both SLNB and CLND. The risk for lymphedema was 0.66% for patients who had SLNB alone and 11.7% for patients with CLND [63]. It has been cited that only 20% of patients will have a positive SLNB result following the procedure and that of those patients only 20% will have non-SLNs that are positive for metastatic disease [64]. Therefore, 96% of patients will have undergone a SLNB and CLND that proved unnecessary in retrospect [65].

Healthcare 2014, 2

244

However, with the current results from the MSLT-I [60], it has shown that the advantage of SLN biopsy and CLND is clear in 10-year disease free survival and melanoma specific survival. 9. Conclusions Current guidelines for the surgical management of a primary melanoma of the skin are based on Breslow microstaging and call for cutaneous margins of resection of 0.5 cm for MIS, 1.0 cm for melanomas ≤1.0 mm thick, 1–2 cm for melanoma thickness of 1.01–2 mm, 2 cm margins for melanoma thickness of 2.01–4 mm, and 2 cm margins for melanomas >4 mm thick. Although, the role of SLNB, CLND, and TLND continue to be studied, current recommendations include SLNB for Stage IB (includes T1b lesions ≤1.0 with the adverse features of ulceration or ≥1 mitoses/mm2) and Stage II melanomas. CLND is recommended when sentinel nodes contain metastatic deposits. Author Contributions Solmaz Niknam Leilabadi, Amie Chen, Stacy Tsai, and Vinaya Soundararajan made substantial contributions to conception and design, and/or acquisition of data, and/or analysis and interpretation of data. Solmaz Niknam Leilabadi, Howard Silberman and Alex K. Wong participated in drafting the article or revising it critically for important intellectual content. Howard Silberman and Alex K. Wong gave final approval of the version to be submitted and any revised version. Conflicts of Interest The authors declare no conflict of interest. References 1. 2. 3. 4. 5. 6.

Lee, C.; Collichio, F.; Ollila, D.; Moschos, S. Historical review of melanoma treatment and outcomes. Clin. Dermatol. 2013, 31, 141–147. Handley, W.S. The pathology of melanotic growths in relation to their operative treatment. Lancet 1907, 1, 927–996. Kaufmann, R. Surgical management of primary melanoma. Clin. Exp. Dermatol. 2000, 25, 476–481. AJCC Cancer Staging Manual, 7th ed.; Edge, S.B., Byrd, D.R., Compton, C.C., Fritz, A.G., Greene, F.L., Trotti, A., Eds.; Springer: New York, NY, USA, 2010. Levine, S.; Shapiro, R. Surgical treatment of malignant melanoma practical guidelines. Dermatol. Clin. 2012, 30, 487–501. Balch, C.M.; Soong, S.; Ross, M.I.; Urist, M.M.; Karakousis, C.P.; Temple, W.J.; Mihm, M.C.; Barnhill, R.L.; Jewell, W.R.; Wanebo, H.J.; et al. Long-term results of a multi-institutional randomized trial comparing prognostic factors and surgical results for intermediate thickness melanomas (1.0 to 4.0 mm). Intergroup Melanoma Surgical Trial. Ann. Surg. Oncol. 2000, 7, 87–97.

Healthcare 2014, 2 7.

8.

9.

10. 11.

12.

13. 14.

15. 16. 17. 18. 19.

20.

21.

245

Veronesi, U.; Cascinelli, N.; Adamus, J.; Balch, C.; Bandiera, D.; Barchuk, A.; Bufalino, R.; Craig, P.; de Marsillac, J.; Durand, J.C.; et al. Thin stage I primary cutaneous malignant melanoma. Comparison of excision with margins of 1 or 3 cm. N. Engl. J. Med. 1988, 318, 1159–1162. Coit, D.G.; Andtbacka, R.A.; Anker, C.J.; Bichakjian, C.K.; Carson, W.E., III; Daud, A.; Dilawari, R.A.; DiMaio, D.; Guild, V.; Halpern, A.C.; et al. Melanoma: Clinical Practice Guidelines in Oncology. J. Natl. Compr. Canc. Netw. 2012, 10, 366–400. Balch, C.M.; Gershenwald, J.E.; Soong, S.; Thompson, J.F.; Atkins, M.B.; Byrd, D.R.; Buzaid, A.C.; Cochran, A.J.; Coit, D.G.; Ding, S.; et al. Final version of 2009 AJCC melanoma staging and classification. J. Clin. Oncol. 2009, 27, 6199–6206. Ho, V.C.; Milton, G.W.; Sober, A.J. Biopsy of melanoma. In Cutaneous Melanoma, 2nd ed.; Balch, C., Ed.; JB Lippincott: Philadelphia, PA, USA, 1992; pp. 264–268. Australian Cancer Network Melanoma Guidelines Revision Working Party. Biopsy. In Clinical Practice Guidelines for the Management of Melanoma in Australia and New Zealand; Sydney and New Zealand Guidelines Group, The Cancer Council Australia, Australian Cancer Network: Wellington, New Zealand, 2008; pp. 35–39. Coit, D.G.; Thompson, J.A.; Andtbacka, R.; Anker, C.J.; Bichakjian, C.K.; Carson, W.E., III; Daniels, G.A.; Daud, A.; DiMaio, D.; Fleming, M.D.; et al. Melanoma, Version 2.2014. Available online: http://www.nccn.org/ (accessed on 17 April 2014). Erickson, C.; Miller, S.J. Treatment options in melanoma in situ: Topical and radiation therapy, excision and Mohs surgery. Int. J. Derm. 2010, 49, 482–491. Chin-Lenn, L.; Murynka, T.; McKinnon, J.G.; Arlette, J.P. Comparison of outcomes for malignant melanoma of the face treated using mohs micrographic surgery and wide local excision. Dermatol. Surg. 2013, 39, 1637–1645. Whalen, J.; Leone, D. Mohs micrographic surgery for the treatment of malignant melanoma. Clin. Derm. 2009, 27, 597–602. Zitelli, J.A.; Brown, C.; Hanusa, B.H. Mohs Micrographic surgery for the treatment of primary cutaneous melanoma. J. Am. Acad. Dermatol. 1997, 37, 236–245. Hui, A.M.; Jacobson, M.; Markowitz, O.; Brooks, N.A.; Siegel, D.M. Mohs micrographic surgery for the treatment of melanoma. Dermatol. Clin. 2012, 30, 503–515. Kunishige, J.; Brodland, D.; Zitelli, J. Surgical margins for melanoma in situ. J. Am. Acad. Dermatol. 2012, 66, 438–444. National Institutes of Health. Diagnosis and Treatment of Early Melanoma. National Institutes of Health Consensus Development Conference Statement, January 27–29, 1992. NIH Consens. Statement 1992, 10, 1–26. Thomas, J.M.; Newton-Bishop, J.; A’Hern, R.; Coombes, G.; Timmons, M.; Evans, J.; Cook, M.; Theaker, J.; Fallowfield, M.; O’Neill, T.; et al. Excision margins in high-risk malignant melanoma. N. Engl. J. Med. 2004, 350, 757–766. Gillgren, P.; Drzewiecki, K.T.; Niin, M.; Gullestad, H.P.; Hellborg, H.; Mansson-Brahme, E.; Ingvar, C.; Ringborg, U. 2-cm versus 4-cm surgical excision margins for primary cutaneous melanoma thicker than 2 mm: A randomized, multicenter trial. Lancet 2011, 378, 1635–1641.

Healthcare 2014, 2

246

22. Heaton, K.M.; Sussman, J.J.; Gershenwald, J.E.; Lee, J.E.; Reintgen, D.S.; Mansfield, P.F.; Ross, M.I. Surgical margins and prognostic factors in patients with thick (>4 mm) primary melanoma. Ann. Surg. Oncol. 1998, 5, 322–328. 23. Pasquali, S.; Haydu, L.E.; Scolyer, R.A.; Winstanley, J.B.; Spillane, A.J.; Quinn, M.J.; Saw, R.P.; Shannon, K.F.; Stretch, J.R.; Thompson, J.F. The importance of adequate primary tumor excision margins and sentinel node biopsy in achieving optimal locoregional control for patients with thick primary melanomas. Ann. Surg. 2013, 258, 152–157. 24. Phan, G.Q.; Messina, J.L.; Sondak, V.K.; Zager, J.S. Sentinel lymph node biopsy for melanoma: Indications and rationale. Cancer Control. 2009, 16, 234–239. 25. Cochran, A.J.; Essner, R.; Rose, D.M.; Glass, E.C. Principles of sentinel lymph node identification: Background and clinical implications. Langenbecks Arch. Surg. 2000, 385, 252–260. 26. Wong, S.L.; Balch, C.M.; Hurley, P.; Agarwala, S.S.; Akhurst, T.J.; Cochran, A.; Cormier, J.N.; Gorman, M.; Kim, T.Y.; McMasters, K.M.; et al. Sentinel lymph node biopsy for melanoma: American Society of Clinical Oncology and Society of Surgical Oncology joint clinical practice guidelines. J. Clin. Oncol. 2012, 30, 2912–2918. 27. Wong, S.L.; Balch, C.M.; Hurley, P.; Agarwala, S.S.; Akhurst, T.J.; Cochran, A.; Cormier, J.N.; Gorman, M.; Kim, T.Y.; McMasters, K.M.; et al. Sentinel lymph node biopsy for melanoma: American Society of Clinical Oncology and Society of Surgical Oncology joint clinical practice guidelines. Ann. Surg. Oncol. 2012, 19, 3313–3324. 28. Morton, D.L. Overview and update of the phase III Multicenter Selective Lymphadenectomy Trials (MSLT-I and MSLT-II) in melanoma. Clin. Exp. Metastasis 2012, 29, 699–706. 29. Hardin, R.E.; Lange, J.R. Surgical treatment of melanoma patients with early sentinel node involvement. Curr. Treat. Options Oncol. 2012, 13, 318–326. 30. Rutkowski, P.; Nowecki, Z.I.; Zurawski, Z.; Dziewirski, W.; Nasierowska-Guttmejer, A.; Switaj, T.; Ruka, W. In transit/local recurrences in melanoma patients after sentinel node biopsy and therapeutic lymph node dissection. Eur. J. Cancer. 2006, 42, 159–164. 31. Landi, G.; Polverelli, M.; Moscatelli, G.; Morelli, R.; Landi, C.; Fiscelli, O.; Erbazzi, A. Sentinel lymph node biopsy in patients with primary cutaneous melanoma: Study of 455 cases. J. Eur. Acad. Dermatol. Venereol. 2000, 14, 35–45. 32. Mays, M.P.; Martin, R.C.; Burton, A.; Ginter, B.; Edwards, M.J.; Reintgen, D.S.; Ross, M.I.; Urist, M.M.; Stromberg, A.J.; McMasters, K.M.; et al. Should all patients with melanoma between 1 and 2 mm Breslow thickness undergo sentinel lymph node biopsy? Cancer 2010, 116, 1535–1544. 33. Gershenwald, J.E.; Thompson, W.; Mansfield, P.F.; Lee, J.E.; Colome, M.I.; Tseng, C.H.; Lee, J.J.; Balch, C.M.; Reintgen, D.S.; Ross, M.I. Multi-institutional melanoma lymphatic mapping experience: The prognostic value of sentinel lymph node status in 612 stage I or II melanoma patients. J. Clin. Oncol. 1999, 17, 976–983. 34. Coit, D.G.; Olszanski, A.J. Progress in the management of melanoma in 2013. J. Natl. Compr. Cancer Netw. 2013, 11, 645–648. 35. Mozzillo, N.; Pennacchioli, E.; Gandini, S.; Caraco, C.; Crispo, A.; Botti, G.; Lastoria, S.; Barberis, M.; Verrecchia, F.; Testori, A. Sentinel node biopsy in thin and thick melanoma. Ann. Surg. Oncol. 2013, 20, 2780–2786.

Healthcare 2014, 2

247

36. Karakousis, G.C.; Gimotty, P.A.; Botbyl, J.D.; Kesmodel, S.B.; Elder, D.E.; Elenitsas, R.; Ming, M.E.; Guerry, D.; Fraker, D.L.; Czerniecki, B.J.; et al. Predictors of regional nodal disease in patients with thin melanomas. Ann. Surg. Oncol. 2006, 13, 533–541. 37. Kalady, M.F.; White, R.R.; Johnson, J.L.; Tyler, D.S.; Seigler, H.F. Thin melanomas: Predictive lethal characteristics from a 30-year clinical experience. Ann. Surg. 2003, 238, 528–535. 38. Kesmodel, S.B.; Karakousis, G.C.; Botbyl, J.D.; Canter, R.J.; Lewis, R.T.; Wahl, P.M.; Terhune, K.P.; Alavi, A.; Elder, D.E.; Ming, M.E.; et al. Mitotic rate as a predictor of sentinel lymph node positivity in patients with thin melanomas. Ann. Surg. Oncol. 2005, 12, 449–458. 39. Ranieri, J.M.; Wagner, J.D.; Wenck, S.; Johnson, C.S.; Coleman, J.J., 3rd. The prognostic importance of sentinel lymph node biopsy in thin melanoma. Ann. Surg. Oncol. 2006, 13, 927–932. 40. Morton, D.L.; Thompson, J.F.; Essner, R.; Elashoff, R.; Stern, S.L.; Nieweg, O.E.; Roses, D.F.; Karakousis, C.P.; Mozzillo, N.; Reintgen, D.; et al. Validation of the accuracy of intraoperative lymphatic mapping and sentinel lymphadenectomy for early-stage melanoma: A multicenter trial. Multicenter Selective Lymphadenectomy Trial Group. Ann. Surg. 1999, 230, 453–463. 41. Reintgen, D.; Cruse, C.W.; Wells, K.; Berman, C.; Fenske, N.; Glass, F.; Schroer, K.; Heller, R.; Ross, M.; Lyman, G.; et al. The orderly progression of melanoma nodal metastases. Ann. Surg. 1994, 220, 759–767. 42. Morton, D.L.; Wen, D.R.; Wong, J.H.; Economou, J.S.; Cagle, L.A.; Storm, F.K.; Foshag, L.J.; Cochran, A.J. Technical details of intraoperative lymphatic mapping for early stage melanoma. Arch. Surg. 1992, 127, 392–399. 43. Thompson, J.F.; McCarthy, W.H.; Bosch, C.M.; O’Brien, C.J.; Quinn, M.J.; Paramaesvaran, S.; Crotty, K.; McCarthy, S.W.; Uren, R.F.; Howman-Giles, R. Sentinel lymph node status as an indicator of the presence of metastatic melanoma in regional lymph nodes. Melanoma Res. 1995, 5, 255–260. 44. De Rosa, N.; Lyman, G.H.; Silbermins, D.; Valsecchi, M.E.; Pruitt, S.K.; Tyler, D.M.; Lee, W.T. Sentinel node biopsy for head and neck melanoma: A systematic review. Otolaryngol. Head Neck Surg. 2011, 145, 375–382. 45. Coit, D.G.; Andtbacka, R.; Anker, C.; Bichakjian, C.K.; Carson, W.E., III; Daud, A.; DiMaio, D.; Fleming, M.D.; Guild, V.; Halpern, A.C.; et al. Melanoma, version 2.2013, featured updates to the NCCN guidelines. J. Natl. Compr. Cancer Netw. 2013, 11, 395–407. 46. Lens, M.B.; Dawes, M.; Newton-Bishop, J.A.; Goodacre, T. Tumor thickness as a predictor of occult lymph node metastases in patients with stage I and II melanoma undergoing sentinel lymph node biopsy. Br. J. Surg. 2002, 89, 1223–1227. 47. Cherpelis, B.S.; Haddad, F.; Messina, J.; Cantor, A.B.; Fitzmorris, K.; Reintgen, D.S.; Fenske, N.A.; Glass, L.F. Sentinel lymph node micrometastasis and other histologic factors that predict outcome in patients with thicker melanomas. J. Am. Acad. Dermatol. 2001, 44, 762–766. 48. Oliveira Filho, R.S.; Silva, A.M.; Oliveira, D.A.; Oliveira, G.G.; Nahas, F.X. Sentinel node biopsy should not be recommended for patients with thick melanoma. Rev. Col. Bras. Cir. 2013, 40, 127–129.

Healthcare 2014, 2

248

49. Nowecki, Z.I.; Rutkowski, P.; Michej, W. The survival benefit to patients with positive sentinel node melanoma after completion lymph node dissection may be limited to the subgroup with a primary lesion Breslow thickness greater than 1.0 and less than or equal to 4 mm (pT2-pT3). Ann. Surg. Oncol. 2008, 15, 2223–2234. 50. Gershenwald, J.E.; Mansfield, P.F.; Lee, J.E.; Ross, M.I. Role for lymphatic mapping and sentinel lymph node biopsy in patients with thick (> or = 4 mm) primary melanoma. Ann. Surg. Oncol. 2000, 7, 160–165. 51. Satzger, I.; Volker, B.; Meier, A.; Kapp, A.; Gutzmer, R. Criteria in sentinel lymph nodes of melanoma patients that predict involvement of nonsentinel lymph nodes. Ann. Surg. Oncol. 2008, 15, 1723–1732. 52. Roka, F.; Mastan, P.; Binder, M.; Okamoto, I.; Mittlboeck, M.; Horvat, R.; Pehamberger, H.; Diem, E. Prediction of non-sentinel node status and outcome in sentinel node-positive melanoma patients. Eur. J. Surg. Oncol. 2008, 34, 82–88. 53. Cochran, A.J.; Wen, D.R.; Huang, R.R.; Wang, H.J.; Elashoff, R.; Morton, D.L. Prediction of metastatic melanoma in nonsentinel nodes and clinical outcome based on the primary melanoma and the sentinel node. Mod. Pathol. 2004, 17, 747–755. 54. Scolyer, R.A.; Li, L.X.; McCarthy, S.W.; Shaw, H.M.; Stretch, J.R.; Sharma, R.; Thompson, J.F. Immunohistochemical stains fail to increase the detection rate of micrometastatic melanoma in completion regional lymph node dissection specimens. Melanoma Res. 2004, 14, 263–268. 55. Gershenwald, J.E.; Andtbacka, R.H.; Prieto, V.G.; Johnson, M.M.; Diwan, A.H.; Lee, J.E.; Mansfield, P.F.; Cormier, J.N.; Schacherer, C.W.; Ross, M.I. Microscopic tumor burden in sentinel lymph nodes predicts synchronous nonsentinel lymph node involvement in patients with melanoma. J. Clin. Oncol. 2008, 26, 4296–303. 56. Kretschmer, L.; Hilgers, R.; Mohrle, M.; Balda, B.R.; Breuninger, H.; Konz, B.; Kunte, C.; Marsch, W.C.; Neumann, C.; Starz, H. Patients with lymphatic metastasis of cutaneous malignant melanoma benefit from sentinel lymphonodectomy and early excision of their nodal disease. Eur. J. Cancer 2004, 40, 212–218. 57. Morton, D.L.; Hoon, D.S.; Cochran, A.J.; Turner, R.R.; Essner, R.; Takeuchi, H.; Wanek, L.A.; Glass, E.; Foshag, L.J.; Hsueh, E.C.; et al. Lymphatic mapping and sentinel lymphadenectomy for early-stage melanoma: Therapeutic utility and implications of nodal microanatomy and molecular staging for improving the accuracy of detection of nodal micrometastases. Ann. Surg. 2003, 238, 538–549. 58. Pasquali, S.; Mocellin, S.; Campana, L.G.; Bonandini, E.; Montesco, M.C.; Tregnaghi, A.; del Fiore, P.; Nitti, D.; Rossi, C.R. Early (sentinel lymph node biopsy-guided) versus delayed lymphadenectomy in melanoma patients with lymph node metastases: Personal experience and literature meta-analysis. Cancer 2010, 116, 1201–1209. 59. Rutkowski, P.; Nowecki, Z.I.; Nasierowska-Guttmejer, A.; Ruka, W. Lymph node status and survival in cutaneous malignant melanoma—Sentinel lymph node biopsy impact. Eur. J. Surg. Oncol. 2003, 29, 611–618. 60. Morton, D.L.; Thompson, J.F.; Cochran, A.J.; Mozzillo, N.; Nieweg, O.E.; Roses, D.F.; Hoekstra, H.J.; Karakousis, C.P.; Puleo, C.A.; Coventry, B.J.; et al. Final trial report of sentinel-node biopsy versus nodal observation in melanoma. N. Engl. J. Med. 2014, 370, 599–609.

Healthcare 2014, 2

249

61. Pilko, G.; Besic, N.; Zgajnar, J.; Hocevar, M. Prognostic heterogeneity after the excision of lymph node metastases in patients with cutaneous melanoma. Surg. Oncol. 2011, 20, 26–34. 62. Twomey, P. Sentinel node biopsy for early-stage melanoma: Accuracy and morbidity in MSLT-1, an international multicenter trial. Ann. Surg. 2007, 245, 156–157. 63. McMasters, K.M.; Noyes, R.D.; Reintgen, D.S.; Goydos, J.S.; Beitsch, P.D.; Davidson, B.S.; Sussman, J.J.; Gershenwald, J.E.; Ross, M.I. Lessons learned from the Sunbelt melanoma trial. J. Surg. Oncol. 2004, 86, 212–223. 64. Torjesen, I. Sentinel node biopsy for melanoma: Unnecessary treatment? Br. Med. J. 2013, 346, E8645. 65. Printz, C. Physicians differ on the use of Sentinel lymph node biopsy for melanoma: Published data receive various interpretations. Cancer 2013, 119, 2515–2516. © 2014 by the authors; licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution license (http://creativecommons.org/licenses/by/3.0/).